JP2015513354A - Dynamic support for footwear - Google Patents

Abstract

The present disclosure can be molded by the back of the foot to provide at least partial support for at least one of the medial arch, lateral arch, transverse arch and metatarsal arch and heel of the wearer's foot It provides a dynamic support that is placed directly under the wearer's heel. The present disclosure provides a customized insole that contains a dynamic member that can be adjusted relative to the contour of the heel and at least a portion of the wearer's arch of such insole. The present disclosure provides a customized insole containing a contoured support.

Description

  The present disclosure relates to shoe supports that can continue to provide customized support for the wearer's foot heel and one or more arches. More particularly, the present disclosure relates to a support disposed on the inside of a shoe that can provide support to a foot portion using both a static support shell and a dynamic support component.

  In the prior art, various methods are known for capturing and supporting the contours of a wearer's foot, but in particular against the multiple arches and heels of the foot, especially the medial arch and lateral side of the wearer's foot There is no cheap, uncomplicated, clean, and accurate methodology for providing dynamic support for.

  Thus, in many applications and backgrounds, such as, but not limited to, customized foot support, footwear, etc., dynamic support or articles including dynamic support that provide customized support for the sole surface of the foot Is needed.

  The present disclosure can be molded with the back of the foot to provide at least partial support for at least one of the wearer's foot medial arch, lateral arch, transverse and metatarsal arch and heel. Provide a dynamic support that is disposed directly under the wearer's heel.

  The present disclosure provides a customized insole containing a dynamic member that can accommodate at least a portion of the arch profile and arch of the wearer of such insole.

  The present disclosure provides a customized insole including contoured support and dynamic support that provides both a wearer's foot heel and a customized arch support for at least one arch.

  The present disclosure provides a midsole that includes a dynamic support that can be molded by the back of the foot to provide at least partial support for one of the plurality of arches of the wearer's foot.

  The present disclosure provides a support shell molded to support a plurality of arches of a wearer's foot, particularly a lateral arch, a metatarsal arch, a medial arch and a transverse arch of the wearer's foot.

  Another embodiment includes a resilient spacer disposed between the base support shell or embedded portion of the shoe and the dynamic support of the heel portion.

  Yet another embodiment includes a footwear support that includes a dynamic support capable of molding a plantar surface portion of the foot, the dynamic support being a fluid material combined with a lubricity enhancer. The fluid material is a highly viscous fluid material containing silicone. The lubricity enhancer is at least one material selected from the group consisting of polytetrafluoroethylene (PTFE) and grease.

  Further embodiments include footwear support including a dynamic support capable of molding a plantar surface portion of the foot, the dynamic support including a U-shaped member and either a gas or fluid disposed thereon.

Fig. 4 illustrates dynamic support according to the present disclosure. Fig. 4 shows an insole for placement on footwear with dynamic support according to the present disclosure. Fig. 5 shows an insole with dynamic support in the heel region. FIG. 6 shows a top view of a base support shell with dynamic support in accordance with the present disclosure. FIG. 3 shows a cross-sectional view of the base support shell and dynamic support of FIG. 2 as viewed from line 3-3. Figure 3 shows a cross section of a package for holding dynamic support particles. FIG. 6 shows a cross-section of a package that includes a resilient spacer disposed below the dynamic particle support in the heel region in accordance with another embodiment of the present disclosure as well as holding particles of a dynamic support similar to FIG. 4 above. Fig. 4 illustrates dynamic support according to the present disclosure. FIG. 4 shows a second top view of a base support shell with dynamic support according to the present disclosure. The perspective view of the base support seen from the medial side is shown. The perspective view of the base support shell seen from the lateral side is shown. Fig. 5 shows a further perspective view of the base support shell as seen from the medial side. FIG. 4 shows a bottom view of a base support shell according to the present disclosure. Fig. 4 shows a side view of a base support shell with support elements. Figure 3 shows a rear view of a base support shell with support elements. Fig. 3 shows the medial side of a base support shell having a support element and a reinforced support structure. FIG. 3 illustrates components of a first embodiment of an insole in an unassembled configuration in accordance with the present disclosure. FIG. Fig. 6 shows a base support shell according to a second embodiment of the insole of the present disclosure. Fig. 6 shows a base support shell according to a third embodiment of the insole of the present disclosure. Fig. 6 shows an unassembled configuration insole having a dynamic support and liner according to a second embodiment of the insole according to the present disclosure; Fig. 6 shows an unassembled configuration insole having a dynamic support and liner according to a third embodiment of the insole according to the present disclosure; Figure 2 shows an insole with secondary dynamic particle support. FIG. 6 illustrates an insole having a secondary dynamic support that further includes a resilient spacer disposed under the dynamic particle support in the heel region in accordance with another embodiment of the present disclosure. FIG. 17 shows an exploded view of the insole of FIG. 16. FIG. 16B shows an exploded view of the insole of FIG. 16A with a resilient spacer. Fig. 4 shows a further embodiment of an insole according to the present disclosure with an additional permeable media layer on top of the dynamic components and / or particles. The midsole for shoes is shown. The midsole for athletic shoes is shown. The midsole for athletic shoes is shown. Fig. 4 illustrates the dynamic support of the present disclosure incorporated into a brace. Fig. 4 illustrates the dynamic support of the present disclosure incorporated into a brace. Fig. 4 illustrates the dynamic support of the present disclosure incorporated into a brace.

  Referring to the drawings, in particular FIG. 1 a, dynamic support is shown and is referenced by reference numeral 150. The dynamic support 150 is a moldable member that deforms to form the wearer's heel and at least one portion of the foot's lateral, medial, metatarsal or transverse arch while wearing the wearer's shoes. Keep the shape. The dynamic support 150 has two arms 8, which have a U-shaped configuration and are arranged under the shoe wearer's heel. The dynamic supports 150 are either connected to each other or to the base 6. The dynamic support 150 is manufactured from a material that allows such dynamic support. These materials support and simultaneously support the wearer's heel. The dynamic support 150 is configured to support at least one portion of the wearer's lateral, medial, metatarsal or transverse arch.

  Although the dynamic support 150 is shown as having a U-shaped configuration, the dynamic support may also have a torus or oval shape. The dynamic support 150 may have an asymmetric shape that adds support to the medial arch and / or the lateral arch.

  The dynamic support 150 can be inserted into the footwear underneath the heel to provide dynamic support for the medial and lateral arches, particularly the rear portion of the medial and lateral arches. Thus, the dynamic support 150 can be inserted inside the shoe.

  Alternatively, as shown in FIG. 1b, the dynamic component 150 can be used with the base support shell 50 as detailed below to form the insole 10 with a particularly customized heel and arch support. The insole 10 includes a base support shell 50, a liner 100, and a dynamic support disposed between the base support shell 50 and the liner 100. FIG. 1 c illustrates the insole 10 and the dynamic support 150 without the liner 100 for clarity.

  With reference to FIGS. 2 and 3, the dynamic support 150 provides support for the posterior medial arch immediately adjacent to the heel portion 45 of the base support shell 50. The dynamic support 150 supports an arch portion adjacent to and immediately below the ribs. The dynamic support 150 may also support the posterior portion of the lateral arch that is outside the wearer's foot.

  FIG. 3 shows a cross-sectional view of the dynamic support 150 disposed inside the base support shell 50. FIG. 3 shows that the dynamic support 150 is pre-contoured with a small radius 152. A liner (not shown) is secured to the top of the dynamic support 150. The dynamic support 150 is disposed on the flange portion 45 of the base support shell 50. The dynamic support 150 is compressed by the wearer under pressure of body weight during walking to provide support for the heel, make the heel comfortable, and provide support for the lateral and medial arch areas of the foot, Make it comfortable. Thus, the dynamic support 150 must be moldable but must retain its shape once molded by the user during wear.

  The dynamic support 150 can be manufactured using various materials. As shown in FIG. 5, the dynamic support 150 may include individually movable components, such as particles 160. Particles 160 may include seeds, such as bird seeds, beads or granules, which are solid or hollow and are wood, polyurethane, polypropylene, polyvinyl chloride, polyethylene fibrous, elastic or solid components. Manufactured from. The particles 160 may include a range of hardnesses to suit the wearer's support needs. Where seeds are used, the seeds may be large or small size seeds. Large and medium size seeds have a diameter of 2 to 3 mm, and small size seeds have a diameter of 1 to 2 mm. The dynamic support 150 may be manufactured from individually movable components that are fibers or strands instead of particles. The fibers may be made from elastic materials such as rubber, polystyrene and elastomeric synthetic materials. The dynamic support 150 may also have a porous outer surface.

  The particles 160 may also include air spheres. Air spheres are manufactured from elastic materials encapsulating air, such as rubber, polystyrene and elastomeric synthetic materials. Therefore, such materials have strong resilience with excellent memory shape recovery. Such materials may have a flexural modulus of 10,000, a specific gravity of 1.209, and a durometer of 45-50 Shore A. The air sphere preferably has a diameter in the range of 1.5 mm to 3 mm and can be compressed and filled with air.

  The particles 160 may be placed in a U-shaped container prior to use for easy handling, as shown in FIG. Particles 160 may be placed in package 163, which is not preformed and therefore does not have a radial extent like the support of FIG. If the package 163 is not pre-formed, flexible packaging must be used to make it stretchable when the package is formed by the user. The preformed package is particularly useful in retail situations where the user may desire to select the dynamic support 150 composition and / or hardness. FIG. 4A shows a resilient spacer 153 disposed under the dynamic particle support 150 in the heel region (not shown). The resilient spacer 153 is approximately 2 mm thick and is preferably formed of an elastomeric material, such as Poron® (eg, a registered trademark of Rogers Corporation for microcell urethane). This spacer 153 enables improved cushioning or shock absorption of the heel region.

  The package 163 may be formed by a process such as injection molding, vacuum forming, or stamping. Alternatively, the package 163 may be formed from a fabric such as polyester. The package 163 may be fixed to the base shell support 50 with an adhesive. Package 163 may be covered with silicone or other resilient material or media for additional cushioning. Spacers 167 may be included between the sides of the package 163 to maintain the position of the particles 160 in the package base support shell 50. The spacer 167 may have a width of about 3.18 to 6.35 mm and may be fixed to the lower surface of the base shell support. Larger spacers from 12.9 mm to 25.40 mm may be used to secure the liner, which covers the particles 160 in place in the package 163. In each of the configurations described above, formed by the consumer, the packaged particles may be surface coated with a layer such as silicone, permeable media (eg screen mesh), polyester fabric, etc. . An adhesive film may be applied to the layer and an additional fabric layer may be used to cover the adhesive film.

  Dynamic support 150 can also be formed by the consumer. The dynamic support 150 may be placed in a package 163 that contains seeds or small particles, which have a material such as epoxy or polyurethane resin. For example, a catalyst that activates the polyurethane, such as water, can be introduced into the contents of the dynamic support 150. Different combinations of catalysts may be mixed with the polyurethane. The consumer can place the dynamic support 150, ie polyurethane and water, in a package 163 that is placed on the shoe for molding during walking. Alternatively, the package 163 may contain a bag containing a water catalyst that can be opened by the consumer during walking. Mixing the water catalyst with the polyurethane activates the polyurethane. The dynamic support 150 will be formed by the consumer during walking.

  Referring to FIG. 5, particles 160 are mixed with media 162 to improve the ability to maintain shape during use to maximize support for the insole wearer. The medium 162, such as polymer silicone, may be used to form the dynamic support 150. The dynamic support 150 can be manufactured to include different ratios of particles 160 and media 162 to achieve the desired characteristics of the dynamic support 150. For example, increasing the ratio of particles 160 to silicon reduces silicone memory and makes the support component 150 softer and more malleable. In other words, media 162, such as silicone, makes dynamic support 150 harder after such media 162 is cured and solidified. The particles 160 may also be wetted with water prior to addition to the medium 162 to reduce the memory of the resulting dynamic support 150. In addition to silicone, the media 162 may also include materials such as urethane, EDPM, or foam materials, such as Etherfoam® or neoprene.

In addition to aligning particles 160 with media 162, lubricant 166 may be added to media 162 to maintain the fluid state of media 162. A lubricant 166, such as PTFE (polytetrafluoroethylene), prevents the silicone from curing very easily and completely solidifying, and further reduces recovery in compression or memory of the silicone. In addition to PTFE, other lubricants such as PTFE grease, grease reinforced with PTFE, liquid polyurethane, ceramic grease and synthetic lubricants such as DuPont are registered trademarks and have a variety of high performance synthetic lubricants ( Krytox (registered trademark), which is a group of oils and greases, can also be used. It is a colorless polymer containing ether functionality. Krytox® oil is a fluorocarbon polymer of polyhexafluoropropylene oxide having the following chemical formula:
_{F- (CF (CF 3) -CF} 2 -O) n -CF 2 CF 3
In the formula, the degree of polymerization n is generally in the range of 10-60. These compounds are collectively known by a number of names including perfluoropolyether (PFPE), perfluoroalkyl ether (PFAE) and perfluoropolyalkyl ether (PFPAE). The unique identifier is CAS registry number 60164-51-4.

  In addition to PFPE, Krytox® grease also contained PTFE telomer, in fact it was made as a liquid or grease form of PTFE. It is heat stable, non-flammable (even in liquid oxygen) and insoluble in water, acids, bases and most organic solvents. It is nonvolatile and useful over a wide temperature range of -75 to 350 ° C or higher. Its high resistance to ionizing radiation makes it useful for the aerospace and nuclear industries. It can also withstand extreme pressures and high mechanical stresses.

  A combination of media 162, such as silicone with a lubricant 166, such as PTFE, along with particles 160 can customize the dynamic support 150 depending on the needs of the individual, while still providing elasticity and the desired moldability, Provide support for heels and arches.

  Fibers, seeds or beads may also be combined with media and / or lubricity enhancers to provide the functions described above with respect to particles 160.

  A malleable, softer dynamic support 150 is obtained with a lower percentage of media 162 (silicone) and lubricant 166 (PTFE), while a harder dynamic support 150 is used with a higher percentage of media 162. (Silicone) is obtained in combination with the particles 160. A support member 150 that is too elastic derived from silicone cannot provide customized support for the wearer's heel and arch by retaining deformation during wear. Conversely, a dynamic support 150 with too much PTFE cannot have some elasticity.

  If the dynamic support 150 does not include the medium 162 and includes the particles 160 along with the lubricant 166, the mesh overlay facilitates a uniform distribution in the dynamic support 150 of the underlying beads or fibers, as shown at 253 in FIG. To do.

  When medium and large seeds are mixed, silicones in the range of 4% to 20% based on seed volume are used. The preferred silicone range is 2% to 10% with respect to the seed volume. Silicone and PTFE have the following volume ratios: 36% silicone and 8% PTFE, 11% silicone and 5% PTFE, 5% silicone and 1% PTFE, and 16% silicone and 8% PTFE. Can be mixed with medium and large seeds. The working range of silicone is 32% to 1% PTFE by volume. When PTFE is used alone with medium and large size seeds, the working range of PTFE is 2% to 12% by volume, with a preferred range of 7% to 10%. Organic materials can also be mixed with medium and large size seeds. For example, peanut butter and flour may be used. 15% -20% peanut butter and 3-5% flour by volume may be used.

  When small seeds are used as particles, small seeds (particles) in the range of 100% for 5% silicone by volume are used. 100% seed by volume, 2% to 8% preferred range of silicone to silicone and PTFE is a small seed with the following volume ratio: 22% silicone + 8% PTFE, 16% silicone and 5% PTFE Can be mixed with. The working range of silicone is 4% to 22% by volume, and PTFE is 3% to 8% by volume. When PTFE is used with a small size seed, the working range of PTFE is 2% to 7% by volume, with a preferred percentage of 6%. Organic materials can also be mixed with small seeds. For example, peanut butter and flour may be used. 15% -20% peanut butter and 3-5% flour by volume may be used.

  Alternatively, support component 150 can be manufactured entirely from media 162 and lubricant 166 or silicone 162 alone. When a combination of silicone and PTFE is used, PTFE in the range of 9% to 16% and silicone in the range of 84% to 91% are used. Silicone in the range of 11% to 12% is preferred for the support component 150 to maintain memory and contour. If the dynamic support 150 includes media 162 and lubricant 166, such material can be pre-packaged (eg, in a package 163) to provide a custom fit.

  The dynamic support 150, which is the medium 162 alone, can also be customized for the user. In order to specifically fit the dynamic support 150, which is the entire medium 162, the medium 162 must be dispensed into the base support shell 50 and covered with the liner 100, as shown in FIG. The user places his / her foot and body weight on the insole and outlines the sole surface of the foot on the dynamic support. After several hours, the dynamic support solidifies and retains the contour of the foot.

  The dynamic support 150 can have various anatomical contours and sizes to adapt to the needs of the user. The dynamic support 150 may be provided in a variety of sizes, narrow, medium and wide to accommodate different sized heel widths. For example, the dynamic support 150 can be specifically structured for children to help with excessive pronation or prolapse. The dynamic support 150 can have various densities depending on the weight of the user. For example, a 22.68 kg child has a dynamic support 150 having a relatively viscous or low density composition, while an adult of 90.72 kg has a dynamic support 150 of a higher density composition. Let's go.

  Referring to FIG. 6, the dynamic support 150 is not limited to the heel portion 45. The dynamic support 150 moves during wear to support the lateral and medial arch portions ahead of the heel. The dynamic support 150 moves to support medial and lateral arch portions that are forward of the heel and not supported by the contoured portion 55 or the lateral portion 54 of the base support shell 50, respectively. Significantly, the dynamic support 150 matches the back of the wearer's medial and lateral arches as such support 150 flows against the contoured portion 55 and the lateral portion 54 of the base support shell 50.

  Together, the dynamic support 150 and the base support shell 50 provide support for the wearer's heel and for at least one of a lateral arch, a medial arch and a transverse arch. The dynamic support 150 and the base support shell 50 each provide partial support for the wearer's arch.

  Referring to FIG. 7, a detailed view of the base support shell 50 according to the first embodiment of the insole 10 viewed from the medial side is shown. 6 and 8, a detailed view of the base support shell 50 according to the first embodiment of the insole 10 viewed from the lateral side is shown. The base shell support 50 has an upper surface 15 and a lower surface 20. Base support shell 50 is molded and structured to support the four arches of the foot, namely the medial arch, lateral arch, metatarsal arch and transverse arch.

  The base support shell 50 includes a lateral side 25 corresponding to the lateral side and lateral arch of the foot, a medial side 30 and sidewall 28 corresponding to the medial side and medial arch of the foot. Sidewall 28 has a height of about 1 inch to accommodate dynamic support 150 (not shown). The base support shell 50 has a front portion 35, a flange portion 45, and a middle portion 40 between the front portion 35 and the flange portion 45. The heel portion 45 has a center heel portion 44.

  Base support shell 50 has a contoured portion 55 that provides partial medial arch support for the wearer's medial arch. In particular, the contoured portion 55 supports the anterior portion of the medial arch proximal to the wearer's metatarsal arch. Contoured portions 55 are in the medial side 30 of the base support shell 50, a portion of the front portion 35, and the middle portion 40 of the base support shell 50. The contoured portion 55 provides a resilient support for the wearer's arch, for example when stress is applied, contracted and released during walking. The contoured portion 55 is forward of the heel portion 45 of the base support shell 50.

  Similarly, the base support shell 50 has a contoured portion 54 that provides partial lateral arch support relative to the wearer's lateral arch. In particular, the contoured portion 54 supports the anterior portion of the lateral arch proximal to the wearer's metatarsal. The contoured portion 54 is on the lateral side 25 of the base support shell 50 and is part of the front portion 35 and part of the middle portion 40 of the base support shell 50. The contoured portion 54 provides resilient support for the wearer's arch when, for example, stress is applied, contracted, and released during walking. The contoured portion 54 is forward of the heel portion 45 of the base support shell 50.

  The dynamic support 150 partially supports both the posterior medial arch and the posterior lateral arch, and provides support for the wearer's medial and lateral arches along with the contoured supports 55 and 54. Being a moldable member, the dynamic support 150 can provide dynamic support for the wearer's posterior medial arch and lateral lateral arch. The dynamic support 150 moves just below the lateral and metatarsal arches of the foot during walking. The dynamic support 150 moves in a direction toward the lateral and medial contoured portions 54 and 55 of the foot. In this manner, both the base support shell 50 and the dynamic support 150 may provide support for the wearer's medial and lateral arch as a whole.

  The base support shell 50 is preferably vacuum molded, injection molded or stamped to be a semi-flexible, semi-rigid or rigid shell depending on user needs. The degree of stiffness is controlled by the thickness at which the base support shell 50 is molded or molded with the reinforcement enhancing element. The base support shell 50 is molded using a material such as polyvinyl chloride (PVC), polyurethane, polypropylene or other plastic. The thickness of the contoured portion 50 is preferably 1 mm to 3 mm.

  The base support shell 50 adapts to the plantar contour of the wearer's foot from the downward stress after several hours of wearing by the user. The contouring of the base shell support 50 may be accelerated by the application of heat.

  The base support shell 50 has a contoured portion 52 that supports the transverse arch and a contoured portion 53 that supports the wearer's metatarsal arch. The contoured portion 52 and the contoured portion 53 are located between the medial-side contoured portion 55 and the lateral-side contoured portion 54. Base support shell 50 is structured to support all four arches. Importantly, all four arches are molded into the base support shell 50 to support the foot medial arch, lateral arch, metatarsal arch and transverse arch.

  Referring to FIG. 9, the additional layer 70 may be secured to the upper surface of the base shell support shell 50. Layer 70 is preferably a thin layer of molding material reinforced, for example, by fiberglass, to provide additional support or strength to the base support shell 50. In use, the layer 70 is selectively applied to the upper surface of the base support shell 50 for additional reinforcement. Alternatively, additional flexibility can be maintained by forming the contoured portions 54, 55 to be thinner compared to other portions of the base support shell 50, such as bending and custom contours during walking. Provides greater elasticity and greater comfort when worn. If additional support is required, the base support shell 50 may be molded to have different thicknesses or include reinforcing geometries. The base support shell 50 may be injection molded, for example, with ribs 53 in the contoured portions 54, 55, providing additional structural support. In particular, the ribs 53 may be selectively placed under the contoured portions 54, 55 molded at the lower surface 20, as shown in FIGS. 10a and 10d.

  FIG. 10 a shows the lower surface 20 of the base support shell 50. The lower surface 20 may have additional support elements 75 and 80. For example, bottom pad 80 is applied to lower bottom surface 20 adjacent contoured portion 55 to provide additional support. An additional pad 75 is applied to the lower surface 20 directly below the transverse arch, metatarsal arch or heel portion 45 to add support. The resilient material of the pads 80 and 75 provides support just below the lower surface 20. The pads 80 and 75 apply an upward stress to the surface 20 by the elastic material from which the pads are constructed. The purpose of the pads 75 and 80 is to augment the metatarsal arch, medial arch and / or lateral arch in addition to the support provided by the base support shell 50 to provide support.

  FIG. 10 b shows the support pad 82 just below the heel portion 45. FIG. 10c shows that the pad 82 may have an asymmetric configuration depending on the needs of the wearer. FIG. 10 d shows the supports 75, 80 and 82 fixed to the back surface of the base support shell 50. There may be four pads so that each of the four pads is located directly under each of the plurality of arches and provides additional support directly under the arches. The pad is removable and may be selectively placed.

  Referring to FIG. 11, a further component of insole 10 is a liner 250. The liner 250 has an upper surface 255 and a lower surface 260, a flange portion 265 and a front portion 263. The liner 250 covers the base support shell 50 and is longer than 2/3 of the length of the base support shell 50. The upper surface 255 of the liner may optionally be covered with a fabric layer that is trimmed to fit the length of the base support shell. The heel portion 265 is shaped to coincide with the heel portion 45 of the base support shell 50 and includes or sandwiches the dynamic support 150 between the liner 250 and the base support shell 50. The liner 250 includes a contoured portion that covers the contoured portions 55 and 54 of the base support shell 50 and the dynamic support 150 and is easily aligned and worn against the contoured portions 55 and 54. A perfect fit for the shoe The liner 250 conforms to the support base shell 50, provides cushioning to the wearer, and secures the support component particles 160 in the insole 10.

  The liner 250 provides cushioning for the wearer's heel. The liner 250 is fixed to the side wall 28, the center portion 44, and the front portion 35 of the base support shell 50 with respect to the base support shell 50. By being secured to the heel center portion 44, the liner 250 ensures that the particles 160 of the dynamic support 150 are properly positioned along the periphery of the base support shell 50 when the dynamic support 150 includes a high percentage of volume. Make sure you stay in. The liner 250 is secured to the base support shell 50 by adhesive, stitching, or snap fit.

  The liner 250 may be injection molded and has areas having various densities, such as a heel area, a medial arch area, a metatarsal arch area, a lateral arch area, and a transverse arch area. For example, the heel region may have a soft density and the arch region may have a higher density than the heel region because it must support the user's weight level. The metatarsal region directly under the toes may be soft to accommodate, for example, diabetic users. Alternatively, if the liner 250 is vacuum formed, it has a uniform density over its length. For additional soft and cushioning effects, a material such as Poron (eg, a registered trademark of Rogers Corporation) may be laminated to the bottom surface of liner 250.

  An additional layer 252 of cushioning material, such as foam or Poron, can be placed between the liner 250 and the base shell support 50 in the heel region 45 to provide an additional cushioning layer for the wearer's heel. Alternatively, the dynamic support 150 can be placed directly on the base support shell 50 and covered with a thin layer of leather to provide a cushioning effect as well. When the dynamic support 150 is made from silicone, such silicone in an uncured state in direct contact with the thin leather layer acts as an adhesive and secures the leather to the dynamic support 150.

  In FIGS. 12 and 14, a second embodiment of the insole is shown and referenced by reference numeral 350. The insole 350 includes a base support shell 300, a top liner 305, and a dynamic support 310. The dynamic support 310 is disposed between the base support shell 300 and the liner 305. The base support shell 300 includes a heel portion 325 because it is structured only to support the wearer's heel. Thus, the base support shell 300 does not have a contoured portion that supports the front end of the wearer's medial arch proximal to the foot metatarsal and flange. The dynamic support 310 disposed on the heel portion 325 supports the medial arch and lateral arch posterior portion of the wearer's heel. The liner 305 has a anatomical heel molded to match the heel portion 325 of the base support shell 350. Referring to FIG. 10c, the medial wedge 82 may be disposed under the dynamic support 310 or the outer medial side. Alternatively, the liner 305 has a molded contour portion that can extend to the entire foot, into which the insole 350 is inserted and embedded. The liner 305 can have a anatomical contour with an additional support thickness in the arch and metatarsal contours or a 2/3 foot length liner.

  Referring to FIGS. 13 and 15, a third embodiment is shown as a full length insole and is referenced by reference numeral 450. The insole 450 includes a base support shell 400, a liner 410 and a dynamic support 420. The dynamic support 420 is disposed between the base support shell 400 and the liner 410. Base support shell 400 is structured to support the wearer's entire foot and includes a heel portion 425, a middle portion 430 and an anterior distal portion 435. Thus, the base support shell 400 has a contoured portion 440 that supports the medial and lateral arches of the wearer's foot. A dynamic support 420 disposed on the heel portion 425 supports the rear portion of the medial and lateral arches disposed proximal to the wearer's heel. The liner 410 has a anatomical ridge shaped to conform to the shape of the heel portion 425 of the base support shell 400. The underside of the insole 450 may include support wedges similar to the pads 75 and 80 of the base support shell 50 in FIG.

  In a third embodiment, secondary dynamic support may be provided at the midsole of the base support shell 50 or the front portion of the insole heel portion 45, as shown in FIG. The secondary dynamic support 151 also includes particles 160 similar to the dynamic support 150 except that the secondary dynamic support 151 has a truncated oval shape and mimics the topography directly under the toes of the midsole or insole. Including, according to embodiments of the present invention, may be positioned to support the anterior portion of the foot. FIG. 16A shows yet another embodiment in which a resilient spacer 153 is disposed under the dynamic particle support 150 of the heel portion 45.

  In the further embodiment shown in FIG. 17, insole 600, in addition to base support shell 50, liner 250 and dynamic support 150, an additional layer 253 covers particles 160 of dynamic support 150. Layer 253 covers particles 160 to contain such particles in heel portion 45 of base support shell 50. Layer 253 may be any such porous layer that may be secured to particles 160 by a permeable medium (eg, screen mesh), polyester fabric, or coating 254. If the coating 254 is made from a material such as silicone, such silicone will penetrate the porous layer 253 and bind to the particles 160. By covering the particle 160 with the layer 253, the particle 160 can move just below the heel and rear portion of the lateral and medial arch and prevent it from being scattered to other parts of the shoe.

  The process of assembling the insole is described below with particular reference to FIGS. 2, 10a, 17 and 18. Regardless of the embodiment of the insole to be assembled, the process is the same. The base support shell 50 is formed using vacuum forming, injection molding or stamping to obtain the desired shape including the portions 54, 55, 52, 53 contoured as desired.

  The base support shell 50 is adaptable when the contoured portion provides a great deal of support in a medial or metatarsal arch. The arch may be lowered, for example, by directing heat from a heat source toward the arch for about 30 seconds to soften the material. The pressure applied to the base shell support 50 by the wearer's weight during walking adjusts the arch to an appropriate height.

  As shown in FIG. 10 a, pads 75 and 80 are selectively placed and secured on the back surface 20 of the base support shell 50 to provide additional support to the central and medial portions of the base support shell 50. Provide support and elasticity. The pads 75 and 80 can be fixed to the lower surface 20 with an adhesive, for example. Pads 75 and 80 can be secured to base support shell 50 at any time after base support shell 50 is formed and cured, and may be removed by a user or wearer.

  FIG. 17A shows a resilient spacer 153 disposed between the dynamic particle support 150 and the top surface of the base support shell 50. In particular, both the resilient spacer 153 and the dynamic particle support 150 are disposed in the heel portion 45.

  Referring to FIG. 18, the dynamic support 150 is disposed on the flange portion 45 of the base support shell 50. A spacer 88 is secured to the center 44 of the heel portion 45 to prevent the dynamic support 150 from moving into this region of the support base shell 50. Alternatively, the spacer 88 can have a long shape to create a channel that maintains the dynamic support 150 around the heel portion 25. The spacer 88 is placed between the arms of the U-shaped dynamic support 150. The spacer 88 is preferably glued to the center of the heel portion 45 and has a thickness of 1 mm to 2 mm. The spacer 88 not only ensures that the dynamic support 150 maintains its position proximate the wall 28 of the heel portion 45, but also provides some support under the wearer's ribs. The spacer 88 also ensures that a suitable volume of dynamic support 150 is disposed proximal to the sidewall 28 to move into the space between the back of the posterior medial and lateral arches and the base support shell 50. Make sure.

  The permeable medium 89 ensures that the dynamic support 150, particularly the particles 160 of the support component 150, do not move from a position between the base support shell 50 and the liner 250, as shown for example in FIG. Can be used to cover the dynamic support 150. The permeable medium 89 is fixed to the sidewall 28 and the spacer 88 by an adhesive, sewing, or snap. The permeable medium 89 also acts like a hammock to distribute the heel pressure against the sides of the dynamic support 150, thus providing some impact resistance to the wearer's heel. For example, a layer of silicone may be placed over the permeable medium as a coating. Although the permeable medium 89 is not required to cover the dynamic support 150 when it contains silicone, the permeable medium 89 provides the stress distribution characteristics described. If the dynamic support 150 includes particles 160 alone, the permeable medium 89 is placed over such particles 160 to prevent migration or dispersal of the particles 160 from between the base support shell 50 and the liner 250. The The permeable media 89 may be covered with a silicone or Poron layer attached. Such a layer of silicone is connected or adhered to the sidewall 28. The silicone layer is dried on the dynamic support 150 for several hours, for example 24 hours. The silicone thin layer durometer preferably has a low hardness. Such durometers are preferably used with a hardness in the range of 10-20. This layer of silicone not only acts to restrict the particles 160 to the heel portion, but also acts as a cushioning layer to make the support component 150 exclusively containing the particles 160 more resilient and soft. . A permeable medium 89 or other material, such as polyester fabric or stretched nylon, is used whenever particles 160 may be released.

  Alternatively, when a silicone coating is placed on the collar 45, it may be applied directly to the surface of the particle 160 alone. After the dynamic support 150 is placed, the liner 250 is preferably placed over the dynamic support 150 and secured to the spacer 88 and sidewall 28 of the base support shell 50. The spacer 88 provides adhesive contact to secure the liner 250 to the base support shell 50 at the center 44 of the heel portion 45.

  The dynamic support 150 may be cured so that the dynamic support 150 is rigid enough to handle during manufacture. After curing, the dynamic support 150 may be covered with silicone or a permeable medium 89 to prevent the particles from dispersing and not reducing the ability of such particle blends to move. The use of the permeable medium 89 is particularly preferred for athletic shoes. When the dynamic support 150 contains PTFE and a lubricant, the dynamic support is deformable and further maintains the support just below the wearer's heel and lateral and medial arches. Alternatively, the dynamic support 150 can consist solely of silicone.

  The liner 250 is then placed over the base support shell 50 and the dynamic support 150 is secured in place. The liner 250 may optionally be disposed over and secured to the permeable media 89 and the silicone layer when such components are used. The liner 250 is placed over the dynamic component 150, preferably after solidification. The liner 250 ensures that the support component 150 does not move from a position between the liner 250 and the base support shell 50. Further, the liner 250 moves the dynamic support between the base support shell 50 and the liner 250 to provide support in the medial and lateral arch areas.

  FIG. 19 shows a midsole 500 having a dynamic support 510 and a base support shell 50 embedded in a shoe 501. The midsole 500 is actually embedded in the structure of the shoe 501 during the manufacturing process. Base support shell 50 is a pre-manufactured base shell with embedded anatomical contours, in particular medial arches, lateral arches, metatarsal arches and transverse arches. The dynamic support 510 is also placed on the midsole 500 in the manufacturing process using the top liner 515 as previously discussed.

  In an alternative embodiment, the midsole 500 can have a length that is approximately 2/3 that of the shoe 501 and can have an embedded contour portion 520. The midsole 500 also includes a dynamic support 510 in an area that supports the wearer's heel or arch. The dynamic support 510 is supported by a shoe sidewall. In this embodiment, the dynamic support 510 is covered with a material 530, such as leather, toward the end of the shoe. The embedded contour portion 520 provides partial medial and lateral arch support as in previous embodiments of the present disclosure. The dynamic support 510 may be removed from the shoe 501 or replaced depending on the wearer's needs.

  FIG. 19 also shows a midsole 500 having a secondary dynamic support 513 located in the thumb and toe regions. In this embodiment, a flexible permeable medium 515 covers and holds the secondary dynamic support 513 in place. In addition, the particles can also move into the forward metatarsal region to provide a supportive custom fit.

  FIG. 20a shows the medial side of the foot of an athletic shoe 600 having a midsole 605 and an injection molded base sole 610 (the portion removed for clarity). Base sole 610 has an outer top surface 615, a anatomical contour 620, a heel region 625 and a top liner 618. The midsole 605 also has a sole cover 630 and a shoe sole 635. A dynamic support 650 having a substantially U-shaped configuration with particles is placed in the heel region 625 during manufacture. The dynamic support 650 is firmly fixed to the heel region 625 by an adhesive.

  FIG. 20 b shows a cross section of the midsole 605. Midsole 605 also shows a spacer 655 disposed between top liner 618 and base sole 610. The spacer 655 maintains the position of the dynamic support 650 on the side of the heel region 625.

  FIGS. 21 a to 21 c show a dynamic support 150 and a base support shell 950 incorporated into a boot or brace 900. Base support shell 950 is a 2/3 or full length component. The brace 900 has a hinge 903 with a flange 904 that connects the upper boot 905 to the lower boot 910. Both the dynamic support 150 and the base shell support 950 comprise a lateral side and a medial side that support the wearer's lateral and medial arches as described in the previous embodiment. The dynamic support 150 moves while wearing to support a lateral arch, medial side, metatarsal or transverse arch portion.

  While this disclosure describes specific embodiments in detail, it will be understood that there are variations and modifications known to those skilled in the art within the scope of this disclosure. Accordingly, this disclosure is intended to embrace all such alternatives, modifications and variations that fall within the scope of the disclosure as described in this disclosure.

Claims (18)

With a dynamic support that can be molded into a part of the plantar surface of the foot and contains multiple independently movable particles,
Support for footwear.   The support of claim 1, wherein the plurality of independently movable particles are suspended in at least one material selected from the group consisting of a fluid material, a lubricity enhancer, and a catalytic polymer.   The plurality of independently movable particles are selected from the group consisting of seeds, air spheres, polyurethane particles, polypropylene particles, polyvinyl chloride particles, polyethylene particles, elastic rubber particles, solid particles, granules, fibers and strands; The support according to claim 1.   The support according to claim 2, wherein the fluid material is a highly viscous fluid material comprising silicone.   The support according to claim 2, wherein the lubricity enhancer is at least one material selected from the group consisting of polytetrafluoroethylene (PTFE) and grease.   The support of claim 1, wherein the dynamic support exhibits a shape selected from the group consisting of a substantially U-shaped member, a substantially torus-shaped member, and a substantially egg-shaped member. Further including a base support shell having a collar portion;
The support of claim 1, wherein the dynamic support is disposed on and supported by the base support shell.   The base support shell is molded to include a flat portion, a curved wall surrounding the flat portion to form the heel portion, and two or more contoured portions disposed on opposite sides of the flat portion. The support according to claim 7, wherein the support is a part.   9. The contoured portion includes a medial arch support portion disposed on one side of the flat portion and a lateral arch support portion disposed on an opposite side of the flat portion. Support.   The support of claim 7, wherein the base support shell is a flexible component that supports the dynamic support.   The support of claim 7, wherein the base support shell is a moldable member comprising a thermoplastic polymer.   The support according to claim 11, wherein the thermoplastic polymer is selected from the group consisting of polyvinyl chloride (PVC), polyurethane, polypropylene, polyethylene or plastic. An embedded portion of the shoe, and a liner covering the embedded portion of the shoe,
The dynamic support is disposed between the embedded portion of the shoe and the liner that coincides with a portion of the embedded portion of the shoe and the plantar surface of the wearer's foot during wear. The support of claim 1, wherein the support supports at least one arch.   The support of claim 13, wherein the liner comprises a compliant media.   The support of claim 1, further comprising a permeable medium disposed around the independently movable particles.   The support according to claim 7, further comprising a resilient spacer disposed between the base support shell and the dynamic support in the heel portion.   The support of claim 13, further comprising a resilient spacer disposed between the embedded portion of the shoe and the dynamic support. A dynamic support that can be molded into a portion of the plantar surface of the foot, includes a substantially U-shaped member, and includes either a gas or fluid disposed therein;
Support for footwear.

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